KR101024423B1 - Intelligent Electronic Device - Google Patents

Abstract

The present invention relates to an intelligent electronic device (IED) that reads a value detected at each point of a system to be monitored and transmits the value to an upper device in the order defined in the point list. Particularly, the present invention downloads a new point list from an administrator computer. It is configured to update the point list of. Accordingly, it is possible to easily set the point list, which is created to continuously collect data items that need to be collected, in the intelligent electronic device. By reducing the amount of communication and the number of times required to send and receive the necessary data between the host device and the intelligent electronics, the communication efficiency of the SCADA system can be increased, the necessary data can be obtained more easily, and the intelligent function can be minimized while minimizing the interruption of monitoring function. It can improve the performance of electronic devices.

SCADA, Intelligent Electronics, Point Lists, Downloads, Surveillance

Description

Intelligent Electronic Device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an intelligent electronic device. In particular, the present invention relates to an intelligent electronic device, which is used to configure a SCADA system and transmits information detected at various points of various monitoring target systems, such as a power system of a substation, to an upper device in the order defined in the point list. An electronic device (IED).

SCADA systems are currently used in various fields. SCADA (Supervisory Control And Data Acquisition) systems are used to monitor and control the status of various production processes or plant equipment.

Referring to FIG. 1, the system to be monitored 15, such as the power system of a substation, includes sensors (eg, current transformers, transformers) and controllers (eg, breakers) located at each point as subordinate devices. The intelligent electronic device is responsible for monitoring, diagnosis, protection, control, and measurement between the upper device 11 and the lower device.

On the other hand, the intelligent electronic device 13 transmits the data sensed at each point to the upper device 11 in the order defined in the point list 19. In the related art, the point list is fixedly set.

Therefore, if each data required by the upper device 11 is distributed randomly in the point list 19, several communications are required to collect all the data.

For example, each item is defined in the order as shown in the point list 19, and the data required by the host device 11 includes R phase voltage, S phase voltage, T phase voltage, R phase current, and S phase. Assume phase current, T phase current, image voltage, image voltage maximum value, reverse phase voltage, reverse phase current.

At this time, if the upper device 11 receives only necessary data from the intelligent storage device 13, a plurality of communication is required as shown in FIG.

That is, the upper device 11 requests the data of the points 0 to 2 to the intelligent electronic device 13, and the intelligent electronic device 13 transmits the corresponding data to the higher device 11 (S21). Requesting data of 13 and transmitting the corresponding data (S22), requesting data of points 101 to 102 and transmitting the corresponding data (S23), requesting data of points 159 to 160 and transmitting the corresponding data A total of four transmission and reception procedures such as (S24) should be made.

This is because the data required by the host apparatus 11 is randomly distributed in the point list.

Alternatively, the data can be configured to import all the data in the point list at once and then select and use the required data.

However, in this case, there is a problem in that the traffic of the entire system is increased, and in general, the increase of unnecessary traffic is further increased considering the fact that several intelligent electronic devices are used to monitor the monitored system 15. It can cause big problems.

As described above, when it is necessary to acquire data discontinuously arranged in the point list of the intelligent electronic device 13, a plurality of requests / response processes are required or a large amount of data including unnecessary information are collectively collected at once. Since there is a need to transmit and receive, there is a problem that the traffic of the system increases and the occupancy time of the communication line increases.

Accordingly, the present invention has been made to solve the above problems, and provides an intelligent electronic device that can easily update the point list to a new one and perform its role without interrupting the original monitoring function of the SCADA system for a long time. There is a purpose.

In order to achieve the above object, an intelligent electronic device according to the present invention basically plays a role of reading a value detected at each point of a system to be monitored and transmitting it to a higher level device according to the order defined in the point list.

In particular, it has a communication port for communicating with the manager computer, it is configured to download a new point list from the manager computer connected through the communication port to update the current point list.

Such an intelligent electronic device may include a data reader unit for reading a value detected at each point of a system to be monitored; A first communication unit for communicating with an upper device; A second communication unit for communicating with a manager computer; A function of transmitting a value read through the data reader unit between the host apparatus connected to the first communication unit in the order defined in the point list, and a new point list between the manager computer connected to the second communication unit. A memory unit for storing a computer program for performing a function of downloading and updating a current point list; And a processor unit operating according to a computer program stored in the memory unit.

The memory unit may be configured using a ferroelectric random access memory (FRAM).

The second communication unit may be configured to communicate with the manager computer through a universal serial bus (USB) scheme.

According to the present invention, the point list of the intelligent electronic device constituting the SCADA system can be easily updated with a new one without stopping the intelligent electronic device for a long time.

This increases the communication efficiency of the SCADA system, enables higher-level devices to more easily acquire the data they need, and improves performance while minimizing interruption of surveillance.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 3, an intelligent electronic device (30) according to the present invention is positioned between the host device 11 and the system to be monitored 15 to build a supervisory control and data acquisition (SCADA) system. do.

The intelligent electronic device 30 basically performs a monitoring role of reading a value detected at each point of the system to be monitored 15 and transmitting it to the upper device 11 in the order defined in the point list.

The intelligent electronic device 30 may be variously configured as necessary to perform various roles such as diagnosis, protection, control, and measurement of the monitoring target system 15 as well as the monitoring function, and the monitoring target system 15 In response to this, several intelligent electronic devices may be used.

In particular, the intelligent electronic device 30 has a communication port 31 for communicating with the manager computer 17, and downloads a new point list from the manager computer 17 connected through the communication port 31. It is configured to update the point list of.

That is, the current point list is set in the same order as in the example shown in FIG. 1, and the data required by the host device 11 is R phase voltage, S phase voltage, T phase voltage, R phase current, and S phase current. , T phase current, image voltage, image voltage maximum value, reverse phase voltage, reverse phase current, it is efficient to update the intelligent electronic device 30 to have a point list 41 as shown in the example shown in FIG.

The manager connects the manager computer 17 to the communication port 31 of the intelligent electronic device 30, and then runs a specific application for downloading the point list to create a point list of the intelligent electronic device 30 as shown in FIG. The new point list 41 is updated.

Then, the R phase voltage, the S phase voltage, the T phase voltage, the R phase current, the S phase current, the T phase current, the image voltage, the image voltage maximum value, the reverse phase voltage, and the reverse phase current data required by the host device 11 are Since they are listed in order, as shown in FIG. 5, the upper device 11 requests data of points 0 to 9 from the intelligent electronic device 30, and the intelligent electronic device 30 sends the corresponding data to the upper device 11. It is possible to collect all the desired data in one process (S51) of transmitting the.

That is, in the embodiment in which the upper device 11 is configured to receive only necessary data from the intelligent electronic device 30, a total of four transmission / reception processes are required in FIG. 2, but in the case of FIG. Only need

The communication port 31 may be configured in various ways according to which communication method the intelligent electronic device 30 and the manager computer 17 are interfaced with, and in the case of using various serial communication methods, a form suitable for the corresponding serial communication method. It consists of.

If the intelligent electronic device 30 and the manager computer 17 are configured to communicate by using a universal serial bus (USB) scheme, it will be configured in the form of a USB port.

A specific embodiment of the intelligent electronic device 60 according to the present invention will be described with reference to FIG. 6.

The first communication unit 61 allows the intelligent electronic device 60 to communicate with each other by being connected to the host device 11 through a predetermined communication network. The first communication unit 61 may be configured in various ways according to the manner in which the upper device 11 and the intelligent electronic device 60 communicate with each other. For example, the first communication unit 61 is connected through a local area network (LAN). Can be configured to communicate.

The second communication unit 62 allows the intelligent electronic device 60 to communicate with the manager computer 17 to communicate with each other.

The manager may update the point list of the intelligent electronic device 60 by connecting the manager computer 17 to the second communication unit 62, and the manager computer 17 may include an application program related to the download of the point list. The application program may be configured to allow an administrator to easily transmit a point list to the intelligent electronic device 60 through an intuitive user interface (UI).

The second communication unit 62 may be configured in various ways according to which communication method the interface between the intelligent electronic device 60 and the manager computer 17 is to be interfaced.

As an example, if the intelligent electronic device 60 and the manager computer 17 are configured to communicate using a universal serial bus (USB) scheme, the intelligent electronic device 60 and the manager computer 17 are configured to include a USB port.

The data reader 63 interfaces with sensors located at each point of the monitoring target system to read a value detected by each sensor.

The memory unit 64 is a component that stores various computer programs for operating the intelligent electronic device 60 and may be configured using a nonvolatile volatile memory device.

As one example, the memory unit 64 may be configured by using a ferroelectric random access memory (FRAM).

FRAM is a read / write nonvolatile semiconductor memory that combines the advantages of SRAM (Static Radom Access Memory), which is fast to read and write, and of the advantages of nonvolatile and electronic programmable memory (EPROM). Branch is a memory element.

The computer program stored and maintained in the memory unit 64 may be variously configured as necessary, and basically, through the data reader unit 63, with the host device 11 connected to the first communication unit 61. And a computer program for performing the function of transferring the read data in the order defined in the point list.

Data transmission between the upper device 11 and the intelligent electronic device 60 may be performed periodically, when a specific situation occurs, or according to a request from the upper device 11.

In particular, the memory unit 64 stores a computer program for downloading a new point list and updating a current point list between the manager computer 17 connected to the second communication unit 62 in accordance with the present invention. do.

The processor unit 65 operates according to a computer program stored in the memory unit 64. In general, the processor unit 65 includes a central processing unit (CPU) and a RAM for storing temporary data during operation. It can be configured to include.

When the intelligent electronic device 60 is turned on, the processor unit 65 starts the computer program stored in the memory unit 64 to start operating in the basic operation mode.

In the basic operation mode, the processor unit 65 transmits the data read through the data reader unit 63 in the order defined in the point list between the host device 11 connected through the first communication unit 61. Perform the action.

In addition, when the manager computer 17 is connected through the second communication unit 62, the manager computer 17 operates in a point update mode in which a new point list is downloaded from the manager computer 17 and the current point list is updated.

Referring to FIG. 7, an example of a process in which the intelligent electronic device 60 downloads a new point list from the manager computer 17 connected through the second communication unit 62 and updates the current point list will be described.

First, when the manager computer 17 is connected through the second communication unit 62 to start the download process (S71), the processor unit 65 temporarily stops the role of the data reader unit 63 (S72). .

Step S72 may be performed by setting an update flag, which is designated to set whether or not a point list update process is currently in progress, to an activated state.

The processor unit 65 downloads a new point list from the manager computer 17 and updates the current point list (S73).

When the point list update in step S73 ends, the processor unit 65 reactivates the function of the data reader unit 63 suspended in step S72 (S74). That is, the update flag is set to an inactive state.

The processor unit 65 may perform the operation of transmitting the data read through the data reader unit 63 to the higher level device 11 in the order defined in the newly updated point list.

As described above, according to the present invention, the user can define a point list for remote communication possessed by the intelligent electronic device 60, and update the defined new point list. Accordingly, when the point list needs to be changed, the point list may be changed without rebooting the intelligent electronic device 60.

The above-described embodiments are intended to help the understanding of the present invention, and the present invention is not limited to the above-described embodiments and can be variously modified and implemented by those skilled in the art without departing from the spirit of the present invention. to be.

1 is an overview of the SCADA system,

2 is an example of a process of exchanging data between a conventional upper device and an intelligent electronic device;

3 is an embodiment of an intelligent electronic device according to the present invention;

4 is an example for explaining a point list to be updated;

5 is an example of a process in which an upper device and an intelligent electronic device exchange data according to the present invention;

6 is a detailed embodiment of an intelligent electronic device according to the present invention;

7 is an example of a process of downloading a point list in an intelligent electronic device.

DESCRIPTION OF THE REFERENCE NUMERALS

11: Parent Device 13,30,60: Intelligent Electronics

15: System to be monitored 17: Administrator computer

31: communication port 61: the first communication unit

62: second communication unit 63: data reader unit

64: memory section 65: processor section

Claims (4)

In an intelligent electronic device (IED) that reads a value detected at each point of a system to be monitored and transmits it to an upper device in the order defined in the point list, Further provided with a communication port for communicating with the administrator computer, And download a new point list from an administrator computer connected through the communication port, and update the current point list. A data reader for reading a value detected at each point of the monitored system; A first communication unit for communicating with an upper device; A second communication unit for communicating with a manager computer; A function of transmitting a value read through the data reader unit between the host apparatus connected to the first communication unit in the order defined in the point list, and downloading a new point list between the manager computer connected to the second communication unit. A memory unit for storing a computer program for receiving and updating a current point list; And Intelligent electronic device comprising a processor for operating in accordance with a computer program stored in the memory. The method of claim 2, And the memory unit comprises a ferroelectric random access memory (FRAM). The method of claim 2, And the second communication unit is configured to communicate with the manager computer through a universal serial bus (USB) method.

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